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Line 1: {{Short description\|Differentiable function whose derivative is not Riemann integrable}} In [[mathematics]], '''Volterra's function''' is a real-valued function ''V(x)'' defined on the [[real line]] '''R''' with the following curious set of properties:▼ {{more citations needed\|date=August 2024}} [[File:Volterra function.svg\|thumb\|400px\|right\|The first three steps in the construction of Volterra's function.]] * ''V(x)'' is [[differentiable]] everywhere▼ * The derivative ''V′(x)'' is [[bounded function\|bounded]] everywhere▼ ▲In [[mathematics]], '''Volterra's function''', named for [[Vito Volterra]], is a [[real-valued function]] ''V~~(x)~~'' [[Function of a real variable\|defined on the [[real line]] '''R''' with the following curious ~~set~~combination of properties: * The derivative is not [[Riemann integration\|Riemann-integrable]]▼ ▲* ''V~~(x)~~'' is [[Differentiable function\|differentiable]] everywhere ▲* The derivative ''V'' ′~~(x)''~~ is [[bounded function\|bounded]] everywhere ▲* The derivative is not [[Riemann integration\|Riemann-integrable]]. ==Definition and construction== The function is defined by making use of the [[Smith–Volterra–Cantor set]] and an infinite number or "copies" of sections of the function defined by The function is defined by making use of the [[Smith-Volterra-Cantor set]] and "copies" of the function defined by ''f(x) = x<sup>2</sup>sin(1/x)'' for ''x'' ≠ 0 and ''f(x) = 0'' for ''x = 0''. The construction of ''V(x)'' begins by determining the largest value of ''x'' in the interval [0, 1/8] for which ''f ′(x) = 0''. Once this value (say ''x<sub>0</sub>'') is determined, extend the function to the right with a constant value of ''f(x<sub>0</sub>)'' up to and including the point 1/8. Once this is done, a mirror image of the function can be created starting at the point 1/4 and extending downward towards 0. This function, which we call ''f<sub>1</sub>(x)'', will be defined to be 0 outside of the interval [0, 1/4]. We then translate this function to the interval [3/8, 5/8] so that the function is nonzero only on the middle interval as removed by the [[Smith-Volterra-Cantor set\|SVC]]. To construct ''f<sub>2</sub>(x)'', ''f ′(x)'' is then considered on the smaller interval 1/16 and two translated copies of the resulting function are added to ''f<sub>1</sub>(x)''. Volterra's function then results by repeating this procedure for every interval removed in the construction of the [[Smith-Volterra-Cantor set\|SVC]].▼ :<math>f(x) = \begin{cases} x^2 \sin(1/x), & x \ne 0 \\ 0, & x = 0.\end{cases}</math> ▲~~The function is defined by making use of the [[Smith-Volterra-Cantor set]] and "copies" of the function defined by ''f(x) = x<sup>2</sup>sin(1/x)'' for ''x'' ≠ 0 and ''f(x) = 0'' for ''x = 0''.~~ The construction of ''V~~(x)~~'' begins by determining the largest value of ''x'' in the interval [0, 1/8] for which ''f'' ′(''x'') = 0''. Once this value (say ''x''<sub>0</sub>'') is determined, extend the function to the right with a constant value of ''f''(''x''<sub>0</sub>)'' up to and including the point 1/8. Once this is done, a mirror image of the function can be created starting at the point 1/4 and extending downward towards 0. This function~~, which we call ''f<sub>1</sub>(x)'',~~ will be defined to be 0 outside of the interval [0, 1/4]. We then translate this function to the interval [3/8, 5/8] so that the resulting function, iswhich ~~nonzero~~we ~~only on the middle interval as removed by the [[Smith-Volterra-Cantor set\|SVC]]. To construct~~call ''f''<sub>21</sub>~~(x)''~~, ~~''f ′(x)''~~ is ~~then~~nonzero ~~considered~~only on the ~~smaller~~middle interval ~~1/16 and two translated copies~~ of the ~~resulting function are added to ''f<sub>1</sub>(x)''. Volterra's function then results by repeating this procedure for every interval removed in the construction~~complement of the ~~[[Smith-Volterra-Cantor~~Smith–Volterra–Cantor set~~\|SVC]]~~. To construct ''f''<sub>2</sub>, ''f'' ′ is then considered on the smaller interval [0,1/32], truncated at the last place the derivative is zero, extended, and mirrored the same way as before, and two translated copies of the resulting function are added to ''f''<sub>1</sub> to produce the function ''f''<sub>2</sub>. Volterra's function then results by repeating this procedure for every interval removed in the construction of the Smith–Volterra–Cantor set; in other words, the function ''V'' is the limit of the sequence of functions ''f''<sub>1</sub>, ''f''<sub>2</sub>, ... ==Further properties== Volterra's function is differentiable everywhere just as ''f~~(x)~~'' (as defined above) is. ~~The~~One ~~derivative~~can show that ''Vf'' ′(''x'') = 2''x'' issin(1/''x'') ~~discontinuous~~- atcos(1/''x'') ~~the~~for ~~endpoints~~''x'' of≠ ~~every~~0, ~~interval~~which ~~removed~~means that in ~~the~~any ~~construction~~neighborhood of ~~the [[Smith-Volterra-Cantor set\|SVC]]~~zero, ~~but~~there ~~the~~are ~~function~~points iswhere ~~differentiable~~''f'' at′ ~~these~~takes ~~points~~values ~~with~~1 ~~value~~and 0−1. ~~Furthermore, in any neighbourhood of such a point~~Thus there are points where ''V'' ′~~(x)''~~ takes values 1 and -−1. in Itevery ~~follows~~neighborhood ~~that~~of iteach isof ~~not~~the ~~possible,~~endpoints ~~for~~of ~~every~~intervals ~~<math>\epsilon</math>~~removed >in 0,the ~~to find a partition~~construction of the ~~real~~[[Smith–Volterra–Cantor ~~line~~set]] ~~such~~''S''. ~~that~~In fact, ''\|V'' ′~~(x<sub>2</sub>)~~ -is discontinuous at every point of ''S'', even though ''V~~′(x<sub>1</sub>)\|~~'' <itself ~~<math>\epsilon</math>~~is ondifferentiable at every ~~interval~~point of [''~~x<sub>1</sub>~~S'', with derivative 0. However, ''~~x<sub>2</sub>~~V''] of′ is continuous on each interval removed in the ~~partition.~~construction of ~~Therefore~~''S'', so the ~~derivative~~set of discontinuities of ''V'' ′~~(x)''~~ is ~~not~~equal ~~Riemann~~to ~~integrable~~''S''. Since the Smith–Volterra–Cantor set ''S'' has positive [[Lebesgue measure]], this means that ''V'' ′ is discontinuous on a set of positive measure. By [[Riemann integral#Integrability\|Lebesgue's criterion for Riemann integrability]], ''V'' ′ is not Riemann integrable. If one were to repeat the construction of Volterra's function with the ordinary measure-0 Cantor set ''C'' in place of the "fat" (positive-measure) Cantor set ''S'', one would obtain a function with many similar properties, but the derivative would then be discontinuous on the measure-0 set ''C'' instead of the positive-measure set ''S'', and so the resulting function would have a Riemann integrable derivative. ==See also== * [[Fundamental theorem of calculus]] ==References== {{Reflist}} ==External ~~link~~links== * [http://www.macalester.edu/~bressoud/talks/AlleghenyCollege/Wrestling.pdf ''Wrestling with the Fundamental Theorem of Calculus: Volterra's function''] {{Webarchive\|url=https://web.archive.org/web/20201123131325/http://www.macalester.edu/~bressoud/talks/AlleghenyCollege/Wrestling.pdf \|date=2020-11-23 }}, talk by [[David Bressoud\|David Marius Bressoud]] * http://www.macalester.edu/~bressoud/talks/Volterra-4.pdf * [http://www.macalester.edu/~bressoud/talks/apnc2004/Volterra.ppt ''Volterra's example of a derivative that is not integrable'' ] {{Webarchive\|url=https://web.archive.org/web/20160303185034/http://www.macalester.edu/~bressoud/talks/apnc2004/Volterra.ppt \|date=2016-03-03 }}('''PPT'''), talk by [[David Bressoud\|David Marius Bressoud]] [[Category:Fractals]]